Micro-power low-offset instrumentation amplifier IC design for biomedical system applications

This work presents a micro-power low-offset CMOS instrumentation amplifier integrated circuit with a large operating range for biomedical system applications. The equivalent input offset voltage is improved using a new circuit technique of offset cancellation that involves a two-phase clocking scheme with a frequency of 20 kHz. Channel charge injection is cancelled by the symmetrical circuit topology. With the wide-swing cascode bias circuit design, this amplifier realizes a very high power-supply rejection ratio (PSRR), and can be operated at single supply voltage in the range between 2.5-7.5 V. It was fabricated using 0.5-/spl mu/m double-poly double-metal n-well CMOS technology, and occupies a die area of 0.2 mm/sup 2/. This amplifier achieves a 160-/spl mu/V typical input offset voltage, 0.05% gain linearity, greater than 102-dB PSRR, an input-referred rms noise voltage of 45 /spl mu/V, and a current consumption of 61 /spl mu/A at a low supply voltage of 2.5 V. Experimental results indicate that the proposed amplifier can process the input electrocardiogram signal of a patient monitoring system and other portable biomedical devices.     

Low-power low-voltage reference using peaking current mirror circuit

A low-power low-voltage bandgap reference using the peaking current mirror circuit with MOSFETs operated in the subthreshold region is presented. A demonstrative chip was fabricated in 0.35 /spl mu/m CMOS technology, achieving the minimum supply voltage 1.4 V, the reference voltage around 580 mV, the temperature coefficient 62 ppm//spl deg/C, the supplied current 2.3 /spl mu/A, and the power supply noise rejection ratio of -84 dB at 1 kHz.     

Low-leakage current, low-area voltage regulator for system-on-a-chip processors

A low-leakage current, low-area voltage regulator for system-on-a-chip processors is proposed. The system is demonstrated in a 0.13 /spl mu/m CMOS technology with a supply voltage varied between 0.8 and 1.5 V. Using this system, the leakage current and power are reduced by as much as 44/spl times/ and 33/spl times/, respectively, compared to conventional topologies.     

A new CMOS pixel structure for low-dark-current and large-array-size still imager applications

A pixel structure for still CMOS imager application called the pseudoactive pixel sensor (PAPS) is proposed and analyzed in this paper. It has the advantages of a low dark current, high signal-to-noise ratio, and a high fill factor over the conventional passive pixel sensor imager or active pixel sensor imager. The readout circuit called the zero-bias column buffer-direct-injection structure is also proposed to suppress both the dark current of the photodiode and the leakage current of row switches by keeping both biases of photodiode and the parasitic p-n junction in the column bus at or near zero voltage. The improved double delta sampling circuits are also used to suppress fixed pattern noise, clock feedthrough noise, and channel charge injection. An experimental chip of the proposed PAPS CMOS imager with the format of 352/spl times/288 (CIF) has been fabricated by using a 0.25-/spl mu/m single-poly-five-level-metal (1P5M) n-well CMOS process. The pixel size is 5.8 /spl mu/m/spl times/5.8 /spl mu/m. The pixel readout speed is from 100 kHz to 10 MHz, corresponding to the maximum frame rate above 30 frames/s. The proposed still CMOS imager has a fill factor of 58%, chip size of 3660 /spl mu/m/spl times/3500 /spl mu/m, and power dissipation of 24 mW under the power supply of 3.3 V. The experimental chip has successfully demonstrated the function of the proposed new PAPS structure. It can be applied in the design of large-array-size still CMOS imager systems with a low dark current and high resolution.     

A CMOS voltage reference based on weighted /spl Delta/V/sub GS/ for CMOS low-dropout linear regulators

A CMOS voltage reference, which is based on the weighted difference of the gate-source voltages of an NMOST and a PMOST operating in saturation region, is presented. The voltage reference is designed for CMOS low-dropout linear regulators and has been implemented in a standard 0.6-/spl mu/m CMOS technology (V/sub thn//spl ap/|V/sub thp/|/spl ap/0.9 V at 0/spl deg/C). The occupied chip area is 0.055 mm/sup 2/. The minimum supply voltage is 1.4 V, and the maximum supply current is 9.7 /spl mu/A. A typical mean uncalibrated temperature coefficient of 36.9 ppm//spl deg/C is achieved, and the typical mean line regulation is /spl plusmn/0.083%/V. The power-supply rejection ratio without any filtering capacitor at 100 Hz and 10 MHz are -47 and -20 dB, respectively. Moreover, the measured noise density with a 100-nF filtering capacitor at 100 Hz is 152 nV//spl radic/(Hz) and that at 100 kHz is 1.6 nV//spl radic/(Hz).     

A 44-/spl mu/W 4.3-GHz injection-locked frequency divider with 2.3-GHz locking range

A microwatt frequency divider for the 2.5-GHz ISM band is proposed. This divider directly modulates the output in a ring oscillator by means of a switch and realizes low power consumption with low supply voltage and a wide locking range. It is fabricated using a five-layer-metal and 0.2-/spl mu/m-gate length CMOS process. The core size is 10.8/spl times/10.5 /spl mu/m/sup 2/, which is much smaller than that of a typical inductor-enhanced frequency divider. This divider operates with a supply voltage in the range from 1.8 to 0.7V, and attains minimum power consumption of 44 /spl mu/W, in which case the supply voltage is 0.7 V, the maximum operating frequency is 4.3 GHz, and the locking range is 2.3 GHz. A derivation of the frequency locking range of the divider is provided in the Appendix.     

1.5 V 1 K-CMOS-RAM with only 8 pins

A 256-bit/spl times/4-bit static RAM working on a supply voltage down to 1.2 V is described. A serial interface for the address and the data with a 4-bit bus reduces the pincount of the RAM to only 8. Special design techniques to reach the design goal-very low power at a reasonable circuit speed-are discussed in detail. The device is fabricated in a low power silicon gate CMOS process. An operating power of 500 /spl mu/W/MHz and a standby power of less than 1 /spl mu/W at 1.5 V supply voltage was achieved. With this serial interface a cycle time of 1 /spl mu/s at 1.5 V was measured.     

CMOS low dropout linear regulator with single Miller capacitor

A 2-5V 150 mA CMOS low dropout (LDO) linear regulator with a single Miller capacitor of 4pF is presented. The proposed LDO regulator with a bandgap voltage reference has been fabricated in a 0.35 /spl mu/m CMOS process and the active chip area is 485/spl times/586 /spl mu/m. The maximum output current is 150 mA and the regulated output voltage is 1.8 V.     

Low-voltage high-drive CMOS current feedback op-amp

A novel CMOS current feedback op-amp is presented. The solution works using a low supply voltage and provides a wide input/output swing as well as a high current driving capability. Experimental results from a prototype implemented in a 0.35-/spl mu/m technology and powered with 1.5 V are also given. The circuit exhibits a better than 500 kHz closed-loop bandwidth and a /spl plusmn/1 mA current drive capability.     

A very high precision 500-nA CMOS floating-gate analog voltage reference

A floating gate with stored charge technique has been used to implement a precision voltage reference achieving a temperature coefficient (TC) <1 ppm//spl deg/C in CMOS technology. A Fowler-Nordheim tunnel device used as a switch and a poly-poly capacitor form the basis in this reference. Differential dual floating gate architecture helps in achieving extremely low temperature coefficients, and improving power supply rejection. The reference is factory programmed to any value without any trim circuits to within 200 /spl mu/V of its specified value. The floating-gate analog voltage reference (FGAREF) shows a long-term drift of less than 10 ppm//spl radic/1000 h. This circuit is ideal for portable and handheld applications with a total current of only 500 nA. This is done by biasing the buffer amplifier in the subthreshold region of operation. It is fabricated using a 25-V 1.5-/spl mu/m E/sup 2/PROM CMOS technology.     

A monolithic current-mode CMOS DC-DC converter with on-chip current-sensing technique

A monolithic current-mode CMOS DC-DC converter with integrated power switches and a novel on-chip current sensor for feedback control is presented in this paper. With the proposed accurate on-chip current sensor, the sensed inductor current, combined with the internal ramp signal, can be used for current-mode DC-DC converter feedback control. In addition, no external components and no extra I/O pins are needed for the current-mode controller. The DC-DC converter has been fabricated with a standard 0.6-/spl mu/m CMOS process. The measured absolute error between the sensed signal and the inductor current is less than 4%. Experimental results show that this converter with on-chip current sensor can operate from 300 kHz to 1 MHz with supply voltage from 3 to 5.2 V, which is suitable for single-cell lithium-ion battery supply applications. The output ripple voltage is about 20 mV with a 10-/spl mu/F off-chip capacitor and 4.7-/spl mu/H off-chip inductor. The power efficiency is over 80% for load current from 50 to 450 mA.     

Compact implementation of high-performance CMOS current mirror

A high-performance compact current mirror implementation with very low input resistance, very high output resistance, high copying accuracy, low input and output voltage supply requirements and high bandwidth is proposed. The circuit characteristics are validated with simulations in 0.5 /spl mu/m CMOS technology and with experimental results.     

A 2-V 23-/spl mu/A 5.3-ppm//spl deg/C curvature-compensated CMOS bandgap voltage reference

A high-order curvature-compensated CMOS bandgap reference, which utilizes a temperature-dependent resistor ratio generated by a high-resistive poly resistor and a diffusion resistor, is presented in this paper. Implemented in a standard 0.6-/spl mu/m CMOS technology with V/sub thn//spl ap/|V/sub thp/|/spl ap/0.9 V at 0/spl deg/C, the proposed voltage reference can operate down to a 2-V supply and consumes a maximum supply current of 23 /spl mu/A. A temperature coefficient of 5.3 ppm//spl deg/C at a 2-V supply and a line regulation of /spl plusmn/1.43 mV/V at 27/spl deg/C are achieved. Experimental results show that the temperature drift is reduced by approximately five times when compared with a conventional bandgap reference in the same technology.     

Micropower CMOS S&H circuit for ambient intelligence applications

A novel sample and hold (S&H) circuit is presented based on the use of a class AB CMOS operational transconductance amplifier with very high slew rate and very low static power consumption. The circuit has been fabricated in a 0.5 /spl mu/m double-poly CMOS technology. The quiescent power consumption is only 80 /spl mu/W using a dual supply voltage of /spl plusmn/1.35 V. The S&H occupies 0.075 mm/sup 2/ of silicon area.     

CMOS voltage references using lateral bipolar transistors

Two bandgap references are presented which make use of CMOS compatible lateral bipolar transistors. The circuits are designed to be insensitive to the low beta and alpha current gains of these devices. Their accuracy is not degraded by any amplifier offset. The first reference has an intrinsic low output impedance. Experimental results yield an output voltage which is constant within 2 mV, over the commercial temperature range (0 to 70/spl deg/C), when all the circuits of the same batch are trimmed at a single temperature. The load regulation is 3.5 /spl mu/V//spl mu/A, and the power supply rejection ratio (PSRR) at 100 Hz is 60 dB. Measurements on a second reference yield a PSRR of minimum 77 dB at 100 Hz. Temperature behaviour is identical to the first circuit presented. This circuit requires a supply voltage of only 1.7 V.     

Design of a low-power 3.5-GHz broad-band CMOS transimpedance amplifier for optical transceivers

This paper describes a novel low-power low-noise CMOS voltage-current feedback transimpedance amplifier design using a low-cost Agilent 0.5-/spl mu/m 3M1P CMOS process technology. Theoretical foundations for this transimpedance amplifier by way of gain, bandwidth and noise analysis are developed. The bandwidth of the amplifier was extended using the inductive peaking technique, and, simulation results indicated a -3-dB bandwidth of 3.5 GHz with a transimpedance gain of /spl ap/60 dBohms. The dynamic range of the amplifier was wide enough to enable an output peak-to-peak voltage swing of around 400 mV for a test input current swing of 100 /spl mu/A. The output noise voltage spectral density was 12 nV//spl radic/Hz (with a peak of /spl ap/25 nV//spl radic/Hz), while the input-referred noise current spectral density was below 20 pA//spl radic/Hz within the amplifier frequency band. The amplifier consumes only around 5 mA from a 3.3-V power supply. A test chip implementing the transimpedance amplifier was also fabricated using the low-cost CMOS process.     

A low-voltage folded-switching mixer in 0.18-/spl mu/m CMOS

Scaling of CMOS technologies has a great impact on analog design. The most severe consequence is the reduction of the voltage supply. In this paper, a low voltage, low power, AC-coupled folded-switching mixer with current-reuse is presented. The main advantages of the introduced mixer topology are: high voltage gain, moderate noise figure, moderate linearity, and operation at low supply voltages. Insight into the mixer operation is given by analyzing voltage gain, noise figure (NF), linearity (IIP3), and DC stability. The mixer is designed and implemented in 0.18-/spl mu/m CMOS technology with metal-insulator-metal (MIM) capacitors as an option. The active chip area is 160 /spl mu/m/spl times/200 /spl mu/m. At 2.4 GHz a single side band (SSB) noise figure of 13.9 dB, a voltage gain of 11.9 dB and an IIP3 of -3 dBm are measured at a supply voltage of 1 V and with a power consumption of only 3.2 mW. At a supply voltage of 1.8 V, an SSB noise figure of 12.9 dB, a voltage gain of 16 dB and an IIP3 of 1 dBm are measured at a power consumption of 8.1 mW.     

Compact power-efficient class-AB CMOS exponential voltage to voltage converter

A novel implementation of a rail-to-rail exponential voltage to voltage converter is presented. It is based on a pseudo-exponential approximation that is easily achieved by the nonlinear currents of a class-AB transconductor. Measurement results for a 0.5 /spl mu/m CMOS technology show a 52 dB output voltage range with linearity error less than /spl plusmn/2 dB using a dual supply voltage of /spl plusmn/750 mV. The power dissipation is less than 40 /spl mu/W.     

Low-voltage wideband compact CMOS variable gain amplifier

A novel low-voltage wideband CMOS variable gain amplifier (VGA) is proposed. Using a 0.13 /spl mu/m CMOS technology, the VGA exhibits a linear-dB controllable gain range of 40 dB with a bandwidth in excess of 130 MHz, while drawing only 50 /spl mu/A from a single 1 V power supply voltage.     

Optimised analytic designed 2.5 GHz CMOS VCO

An analytic method for prediction of oscillation amplitude and supply current of differential CMOS oscillators is presented. The validity of this method has been verified by designing an LC CMOS oscillator in a 0.24 /spl mu/m CMOS technology. The predictions are in good agreement with simulation results over a wide range of supply voltage.